Apparatus for manufacture of pulp



Feb. 7, 1939. I A. J. A.. AsPLUND 2,145,851

n APPARATUS FOR MNUFACTURE OF PULP Original Filed Sept. 19, .1934 8 Sheets-Sheet 1 y INVENTOR ATTORNEY Feb. 7, 1939. A. J. A. AsPLuND APPARATUS FOR MANUFACTURE OF PULP 8 Sheets-Sheet 2 Original Filed Sept. 19, 1934 Feb. 7, 1939. A. J. A. AsPLUND AAPPARATUS FOR MANUFACTUR 0F PULP original Filed sept. 19, 1934 8 Sheefts-SheekI 3 INVENTOR BYr Qi ATTORNEY Feb. 7, 1939. A. J. A. AsPLUND 2,145,851

I APPARATUS FOR MANUFACTURE OF PULP original Filed sept. 19, 1934 8 sheets-sheet 4 unimi/1W,

Feb. 7, 1939. A. J. A, ASPLUND 2,145,851

APPARATUS FOR MANUFACTURE OF PULP Original Filed Sept. 19, -1934 8 Sheets-Sheet 5 Feb. 7, 1939. A. J. A. AsPLUND 2,145,851

APPARATUS FOR MANUFACTURE OF PULP Original Filed Sept. 19, 1934 8 Sheets-Sheet 6 Feb. 7, 1939. Al J A ASPLUND 2,145,851

APPARATUS FOR MANUFACTURE O PULP Original Filed Sept. 19, 1934 8 Sheets-Sheet 7 oooooooo MFM@ " V sa INVENTOR ATTORNEY Feb. 7, 1939. A, j- A ASPLUND 2,145,851

APPARATUS FOR MANFACTURE OF PULP Original Filed Sept. 19, 1934 8 Sheets-Sheet 8 .o AQ 229.22. O Y

Patented Feb. 7, 1939 APPARATUS FOR MANUFACTURE F PULP Arne Johan Arthur Asplund, Stockholm, Sweden, assignor to Aktiebolaget Defibrator, Stockholm, Sweden, a corporation of Sweden Original application September 19, 1934, Serial 744,657. Divided and this application September 19, 1934, Serial No. 744,658. In

Sweden March 29, 1932 16 Claims.

'I'his application is a continuation in part of my copending applications Serial No. 611,700, tiled May 16, 1932, and Serial No. 712,326, filed February 21, 1934, and is a division of my copending application Serial No. 744,657 nled concurrently herewith which matured into Patent No. 2,008,892, issued July 23rd, 1935.

n My invention relates to apparatus for the production of pulp from ligne-cellulose materials, ysuch as wood chips, and more particularly to the kproduction of `pulp by what is generally termed a mechanical process. The invention has for its object to materially shorten the time required for the manufacture of pulp and to materially decrease the power consumption required While producing a pulp of high quality.

In mechanical processes the defibration is accomplished by grinding, beating, kneading or other frictional action, which actions generally may be termed abrading, with a softening of Athe lignin by heating.

` In accordance with my invention, the material to-.be heated is subjected to an environment of steam or other gaseous environment, any amount of water present being so small as to be substantiallyv entirely absorbable in the material, the temperature of the environment being above 212 F. and suiciently high to markedly soften l the ligneous substance of the middle lamelle., and

Fig. 2 is a vertical sectional view of part of the plantv taken on the line 2--2 of Fig, 1;

Fig. 3 is a vertical sectional view of pari-)of the plant of Fig, l taken on the line 3-3 of Fig. 1;

Fig. 4 is a sectional view taken on the line 4 4 of Fig. 1; l

Fig. 5 is a sectional view taken on the line 5-5 of Fig.'4;

Fig. 6 isa sectional view taken on the line 6--6 of Fig. 4; Fig. 7 is a sectional view taken on the line 1-1 of Fig. 2;

Fig. 8 is a sectional view taken on the line 8--8 of Fig. 2;

charge apparatus forming part of the plant shown in Fig, 1;

Fig. 13 is a view of valve actuating mechanism taken on the line |3-I3 of Fig. 12;

Fig. 14 is a view of valve actuating mechanism taken on the line I4--I4 of Fig. 12;

Fig. 15 ls an enlarged view of a valve forming part of the discharge structure;

Fig. 16 shows a detail in cross-section taken on the line I6-I6 of Fig. 4;

Fig. 17 shows, in vertical transverse section, another apparatus for carrying out the invention and taken on the line Il-I'I of Fig. 18;

Fig. 18 is a longitudinal/sectional View taken on the line I8-I8 of Fig. 17;

Fig. 19 is a. horizontal longitudinal sectional view through an actual apparatus similar to the apparatus shown in Fig. 17;

Fig, 20 is a vertical sectional view taken on the line 20-20 of Fig. 19;

Fig. 21 is a sectional view taken on the line v2I-2I of Fig, 19;

Fig. 22 is a sectional view taken on the line 22-22 of Fig. 19;

Fig. 23 is afhorizontal sectional view of a modied feeding structure; and

Fig. 24 is a transverse sectional view taken on the line 24-24 of Fig/23.

Referring more particularly to Fig. l, the plant or .system includes feeding apparatus designated generally by the numeral I0, mechanical dellbrating apparatus designated generally by numeral 20, and discharge apparatus designated generally by numeral 30. A motor II drives the Y feeding apparatus through a regulatable variable speed transmission I2 and reduction gearing I3. The reduction gearing drives a crank I4 (see also Fig. 2) including a crank pin I5 on which is mounted a connecting rod I5 having its other end mounted on a wrist pin I'I, in turn mounted on a cross-head I8 mounted to slide in cross-head guide I9. To the cross-head is attached a plunger 2| which due to rotation of the crank, reciprocates Within a cylinder 22 which has an opening 23 adapted to receive the material to be made into pulp. The material may, for example, consist of wood chips of the ordinary size used in pulp manufacture, for example, about one inch long.

Cil

While the apparatus is adapted to produce pulp from other materials than wood chips, such as straw, bamboo and a variety of other ligno-cellulose materials, it will be assumed for purposes of description of the process that wood chips are `being treated. 'I'he woodY chips may be fed to the which may be squeezed from the wood chips byv the plunger action to leave vthe apparatus.v In accordance with the invention, the wood chips supplied to the apparatus are in what may be termed a dry state. By this of course is not meant bone-dry state but a state involving the absence of free water surrounding the chips.

The material fed. to the apparatus preferably has a moisture content not exceeding 60 percent by weight and in the case of very Wet wood it is desirable to first dry the wood before being supplied to the apparatus. While the presence of moisture is desirable, my process is preferably carried out with a minimum of free water. The feeding' apparatus, therefore, acts not alone as a A feeder but also as a. dryer since if the wood is this cutting edge.

very wet the moisture will be squeezed out-of it by the `plunger action and removed at this point so that the material is of substantially the moisture content indicated above when it passes into the steam atmosphere hereinafter to be described. A

Adjacent the inlet 23 is a cutter 28 having a cutting edge directed toward the plunger 21| The plunger on its forward stroke passes alongside of The plunger is formed with a circumferential cutting edge 3| which cooperates with the cutting edge of the cutter 28 to cut the material being fed so that it will. not nd its way in between the plunger 2| and the wall of the cylinder 22.

In practice the plunger is reciprocated many times a minute, for example, 10 to 50 times per minute.

On the forward stroke Iof the plunger, the quantity of wood chips in the cylinder 22 is; forced forward into thegmember 25. Compression of this material takes place, and on the return or back stroke of the plunger the material is held in the member 25 due to the conical projectionsv 26. Thus the wood chips form a stopper at the inlet to the path of flow of chips through the high pressure steam space and assist in maintaining the pressure within said space. The material vmoves through the member 25 and pipe section 32 and enters a receiving vessel 33. The members 22, 25 and 32 constitute a'conduit forming a pathof flow through which the chips are conveyed by means of the plunger 2|, the end surface of which isv disposed transversely to the lengthwise direction of the path. When the plunger is reciprocated this surface exerts a force o n the dry chips in the lengthwise direction vof the path and thus forces the chips to move throughv the path. A check valve34 may be provided at the outlet end of pipe member 32 to prevent too violent a back-dow of wood` chips toward the supply mechanism incase the friction of the material against the walls of the .sup-

ply path to receiver 33 is insufficient to hold the chips from flowing backwards with the plunger. This check valve 34 may also serve to deflect the material into the receiver 33. In thebottom of receiver 33 is a screw-conveyer 36. As shown more clearly in Fig-3, the screw-conveyer is mounted on a driving member 31 passing through a stung box 38 and driven by a motor 39 and gearing 4| (Fig. 1). This screw-conveyer may be driven at constant speed. The conveyer extends into a. connection 42 forming an outlet for the receiver 33 and leading to the central part of the mechanical debrating apparatus 20.

, Connection 42 forms a path of fiow which is a continuation of thepath formed by members ,22, 25 and 32. The forward surface of screw conveyer 36 is inclined with respect to the lengthwise direction of this path and consequently extends transversely thereof. When the conveyer is rotated, this surface exerts a, force on the dry chips in a direction having a component in the lengthwise direction of the path, whereby the chips are caused to move throughl the path formed by connection 42 to the debrating apparatus 20. In the apparatus shown, this device is of the disc-refining or grinding type and may be termed a grinder although it will be understood that other formsof devices may be used depending upon the qualityof the pulp to be produced.

Steam is admittedto the receiver 33 by means of pipes 43 and 44. Mounted on the receiver is a Y pressure gauge 33a and a safety valve 33h. The

bottom of receiver 33 may be provided with a drain connection having a valve 36a therein for draining off freewater. .Assuming that the wood chips are derived from coniferous woods, the steam supplied, which may be regulated in any desired manner, by a hand valve or automatically, is preferably of such temperature as to provide a temperature of between 300 F. and 340 F. in the apparatus. The chips having been supplied at ordinary temperature will act as a condensing medium for the steam. The steam penetrates the pores of the material and condenses in the interior thereof. As the transfer of heat from the steam to the material is carried out at the temperature of condensation, the rate of heating is rapidand the time required to raise the temperature of the material to the aforesaid temperature is not more than 20 to 40 seconds, depending on the original moisture content and temperature of the wood. Material having an initial content higher than 50 percent and a temperature below the freezing point of water requires a. longer time 'before its temperature is raised to the desired degree.

I have found that this treatment of wood acts to markedly soften or to melt the ligneous substance ofthe middle lamella of the wood in a manner analogous to the melting or softening of wax. Although it is not known whether or not the substance in the middle lamella really melts at such temperature, the eifect on the ligno-cellulose material is such as if melting actually were taking place. Although good results have been obtained with lower temperatures as above indicated, and even down to temperatures not materially above 212 F., depending on the character of the material, the best resultsare obtained at higher temperatures. The defibration of coniferous woods is preferably carried out at temperatures from 250 F. to 360 F. and, as above indicated, the best results are obtained at temperaturesbetween 300 F. and 340 F. 'I'he debration of hard woods may be accomplished at somewhat lower temperatures. the best results having been obtained between 280 F. and 300 F. Material derived from straw, bamboo or grass may be satisfactorily treated at still lower temperatures.' 'Ihese temperatures, are, however, lower than the temperatures at which the walls of the individual fibers are disintegrated'and a distinction should be borne in mind between the ligncous substance of the middle lamella, which I iind can be markedly softened or melted by elevation to the temperatures indicated, and the ligneous substance in the fiber walls which withstands highertemperatures before permitting easy destruction of the bers themselves. To

- disintegrate the walls of the fibers without applytral slots of the levers is a member 12 which is king great mechanical effort, it is necessary to heat the material to considerably higher temperatures, at any rate above approximately 390 F.

The screw-conveyer 36 carries the' material into the center ofthe grinder. It will be understood that the material is conveyed in what may be termed dry state and I prefer not to have any free water anywhere in the path of flow of material. The grinder includes a stationary disc.45 and a rotary disc 46 mounted on a shaft 41 journalled in bearings 48 and 49. The discs 45 and 46have mounted thereinA pins 5|, 52 and 53, 54, respectively (Fig. 6). The discs are ried as shown at 5,5. Rotor 46 is secured to the shaft in any suitable manner as by a nut 56. The shaft is driven at constant speed by a pulley 51 keyed thereto driven in turn from a motor 58 by belting 59.

Shaft 41 passes through a stufling box 8| which includes a gland 62 provided with a cooling channel 63. Cooling is also provided at 64 in the main housing of the grinder adjacent the stuffing box. Circulation pipes 65 and 66 (Fig. 10) conduct cooling vfluid to and from the channel 63 and cooling pipes 61 and 68 conduct cooling fluid tov and from the space 64. In addition to cooling, this provides a seal for preventing leakage of steam'from the grinder.

Mounted on the base 69, which supports the grinder, is a pair of levers 1|. Mounted in cenmay be moved closer to each other or farther away from each other. e

A rod 16 is pivotally mounted at 11 on the casing for the grinding discs and carries a disc 18 loosely mounted thereon and adapted to move on the rod by a hand-screw 19.v Disc 18 is positioned within and slidable with respect to a housing member 8| which is mounted on the top ends of the levers 1I at 82. yA spring 83 acts'betwe'en .fthe disc 18 and the housing member 8| to press these members apart. The position of the housing member 8| may be limited and adjusted by hand-wheel 84. vThe purpose of this arrangement is to exert a pressure on the shaft 41 to urge the disc 48 toward the disc 45. `This pressure is adjustable by means of the hand-wheels 19 and 84.

The wood chips fed to the grinder pass through the grinder due mainly to centrifugal force and rpartly due to the forcing of new material into the having a valve port 92 therein. This port is conv trolled by a valve member 93 mounted on a valve stem 94. At its other end, pipe member 88 is flanged, and between such flange and a flange on member 89 is a ported member 95, the port 96 of which is controlled by a valve member 91 mounted on a stem 98. Stems 94 and 98 are spring-pressed by means of springs 99 and |8| into closed position and abutments |82 and |83 on the ends thereof respectively abut against valve rockers I 84 and |85 respectively (Figs. 13 and 14). Member |84 carries a roller |86 which rolls on the periphery of a cam |81 adjustably mounted on a shaft |88 and driven by a motor |89 through a regulatable variable speed mechanism II8 and reduction gearing III. 'I'he cam |81 includes a projection |I2 which moves the roller |86 to the left, as shown in Fig. 13, once for one revolution, to open valve 93 periodically. Mounted on member |85 is a. roller II3 which contacts the periphery of a cam I I4 also mounted on shaft |88 and driven by motor |89. This cam has an extended projected surface as shown in Fig. 14 whereby valve 91 is opened for a substantial portion of a revolution of member II4. However, it will be seen that the cams are so adjusted and constructed that when the one valve is open the other valve is closed respectively. Levers I84a and I85a are provided for holding the valves open manually. When the cams do not act on the valves, 'they are closed partly due to spring pressure and partly due to steam-pressure ahead of the valves.

Assuming that valve 93 is opened, material is forced into pipe section 88 to ll the same. Then valve 93 closes and valve 91 opens whereupon the greater part of this material leaves the pipe section 88 due to thelower outside pressure which generally is atmospheric. When the valve 93 is open the pressure of the steam environment in the grinder is imposed upon the interior of pipe 88. As above indicated, this pressure may be 8 atmospheres or approximately 115 pounds per square inch gauge. It is clear, therefore, that when valve 91 is open the moisture in the pulp will to some extent vaporize and together with the steam pressure therein will cause an expansion which will drive out the pulp through the pipe section 89.

Fig. shows the preferred construction of the valves 93 and 91 wherein the seating periphery of the valve member II5 is morevor less sharp as at I I6 and seats on a flat surface I I1. With this construction I have found that leakage is avoided between the valve face and valve seat due to pulp therebetween. The narrow valve face compresses the pulp so that it, in effect, constitutes a packing between the valve face and valve seat. The pulp n cushions the impactof the valve member on the seat. In operation, the valves are opened and closed many times a minute, for example, 60 to 100 cycles per minute.

When valve 93 is open it will be appreciated that there is a flow of material and steam into discharged through the-valve 93.,v Obviously the time can be increased but vI have found that a .good quality of product can be obtained'withoutu, any greater lengthof treatmentjthan thisin an 'apparatus constructedand operatedras herein'be- 25, which may be facilitated by weighting down check valve 34. lAs soon as a suitableplug* is formed, the steam valve is again opened and the pressure israised to thatv corresponding 'to-the, temperature to be maintained inthefapparatusj the pipe section 88 which would tend to reduce the pressure in the grinding housing. In order to prevent any drop of pressure due to the opening of valve 93 the pipe 44 is connected at a plurality of points |I8, ||9 and |20 to the discharge side of the grinding discs. There is thus free access 'of steam to the discharge' side of the grindingdiscs wherefore the steam pressure is equalized and variation in pressure between these discs is prevented. Without such a by-pass of steam to the outlet side of the grinding discs the reduction in pressure on the discharge side of the' rotating disc due to opening of valve 93 would tend to ,l cause the discs to move apart as ta result of which thelower end of member 1| can be quickly moved v to the left as shown in Fig. 3 whereby the discs 45 and 46 can be quickly moved apart when stopping the apparatus or in case of emergency as when 'a piece of metal might accidentally be carried into the apparatus. Also in starting the ap paratus it is desirable to have the discs' separated so that they will not wear on each other before the wood chips are present between the discs,.-

wherefore this arrangement can also Abe'used for bringing theA discs togetherl when starting opera--k tion.

In starting the system, it is desirable to use the j following procedure. First, the apparatusv is thoroughly heated by' steam. The supply can'be f closed by running the,` plunger 2| inward in the cylinder 22.`l 'I'he outlet valves are operated atj slow speed. At the same time motor is run'to rotate disc 4 6 to throw out condensate through,-

the discharge apparatus. When .,thegapparatus is warm, the steam supply is Shut offand thefeed-V ing apparatus is started andchilsfare fed into` hopper 24. A plug of chipsis formed 'in member Then the conveyer 36 is set in motion.; In- .starting lever |22 is set so as to hold the discs 45 and 46' apart. When chips reach the .discs,'lever v|22 is thrown to press the discs toward each other.

. The presence of chips between ,-the discs can be determined by sound and feel of leverr |22. The speed 'of the discharge apparatus.isfadjus'tedA to' suit the vflow of material as soon as the pulp be` gins to issue from the appara-tus. The tension of spring 83 is nowadjusted to the desired quality o f the pulp produce j v As above indicated, the material may be fed at such a. rate as to take] between 20 and 40 seconds from the time it enters'the receiver 33 until it'is forevdescribed. vIt'isd'esirable'that the velocity I of the material is so great that deiibrationftakes place as soon as the material is raised vto the tem.. j Vp'erature at which` the lignin of the middle 75 lamella ismarkedly softened to'avoidunfavorable autism eil'ects on the materialen account of the l elevated temperature. It has been common to rely on extended soaking or heating to soften the wood or woody vmaterial before the mechanical pulping thereof. Extendeditreatment in 'water or steam` or both acts to affect the wood in a manner ap-` proaching a chemical action. It has ynot been appreciated thatat the temperature which I employ, extended soaking `or digestion is not necessary,.but that the material can be debrated with use of little lpower immediately that it is brought 'up to temperature., I avoid extended treatment and save the heat necessary to heat a mass of water, save circulating liquid and the apparatus f and power required therefor, andshorten thev time involved while at the same time obtaining well debrated and substantially white pulp.

At the same time toorhigh temperatures are avoided in carrying out my invention as I have found that on raising the temperature ofk the ligne-cellulose material to be treated above temperatures around-400 F. does not in anyap- 'f preciable way facilitatev the delbration thereof and no substantial savingl in vpower required can be accomplished by doingfso.- On the other hand, it has been found that in raising the temperature above that point a marked discoloration of the pulp is obtained and at still highertemperatures, such `as around 4:80v F.,destruct ion due exothermic reactions rapidly takes place.

Figs. l-7 and 18 show an apparatus in which Iv have carried out my process on a small scale. The apparatus shown consists of a cylinder 2 hav- `ving `both its Aends 3 and 4 closed-in operation. One of 4the ends maybe removed toplace Wood chipswithin the vessel. Arranged within the cylinder 2 concentrically with the axis thereof isa member adapted-to be rotated vfrom the outside. This member, which resembles the rotating membe'r of a shredder .of the hammer-mill type, consistsof a main.` shaft y5 carrying a plurality of movable'blades 6 attached to shafts 1 parallel to 4.the main shaft Sand secured to hubs 8 fixed to `said shaft 5.v On the inside, the cylindrical vessel "2 is' provided with means such as bars 9,.-or the Ilike v adapted to prevent the enclosed'material from following vthe motion of the rotating mem` bers, said material being on rotation thrown againstth shell off the vessel and then conveyed @against and between the'bl'ades 6 so as to ensure an appropriate circulation of the material. vThe action'of the apparatus is similar4 to that of a dough kneading machine, the debration being I performed essentially through the' rubbing or kneading action of vthev rotating members or blades G and through internal friction between* the particles of the material caused bythe vigorousv` circulation of the same. Steam 'is supplied to the cylinderI through pipe la and a pipe lb, serves to let lout any air or other gases and for reducing vsteam pressure when the apparatus is stopped. 'When the material has been steamed for a suiiicient time, which may be less than a minute, to bring it to the desired temperature,for lexample,

the same temperature as used in the apparatus shown inFi'g. l, the rotor is started and runs for 'sufficient time to separate the fibers which time,

for' example, maybe two orthree minutes.

`It is'not absolutely necessary thatl the blades of the'rotating members be movable. In order to obtain still further veffective deibration of the material the vessel may be 'provided with two or morerotating members of the `type described.'

Inthis apparatus an end cover isremoved to remove the material on finishing the operation but it will be understood that devices may be supplied for continuously feeding and withdrawing the material as in Fig. 1`. A flow of water may be used to remove the pulp but it will be understood that it is characteristic of the process that the material is not soaked in water in carrying 'out the defibration process. The process may be started in one compartment in the presence of small amounts of water, for example, up to '7 pounds of water per pound of dry material after which the deflbration may be continued in another compartment in the presence of greater amounts of waterl but it will be obvious that any great amount of water requires additional power 15 for its movement and free water as such I have found to be unnecessary and undesirable for obtaining the best results and any free water except such as may be necessary to provide a moisture` content with the range or limits herein indicated 20 is undesirable. The power required for the debration of the heated material will be less when `thejquantity of water present is less. When the quantity of water present does not exceed 7 pounds, for instance, but amounts to 1 to 3 pounds 25 per pound of dry material, the material, after applied defibration, has the appearance of a fairly dry paste.

In Figs. 19 through 22, I have shown still another apparatus for carrying outmy invention. a Like parts with respect to the embodiments shown in Fig. 1 are given like reference characters. The system as a whole may be the same as in Fig. 1 with the abrading apparatus of this embodiment substituted for that of Fig. 1. The material ento the inlet |30 of an abrading apparatus analogous to that shown in Figs. 17 and 18. The apparatus includes a cylinder |3| in which is mounted a rotor |32. As shown in Fig. 19, the rotor includes two portions of diferent character and the left-hand part as seen in Fig. 19 is shown on an enlarged scale in Fig. 22. The part to the right in Fig. 19 is shown on an enlarged scale inv `Fig. 21. Adjacent the inlet |30 is a screw |44 for feeding the material to the rst grinding section shown in Fig. 21. This section includes angle members |33 mounted on the center yshaft |34 and having sawed-tooth edges |35. In the periphery of the cylinder is mounted a series of projections of cone like nature |36 formed on removable insets |45 and the projections of the angle members y pass between the projections |36, leaving only a small space'between them when the teeth of the members |33 are aligned with the projections |36. y lIn the second section shown in Fig. 22, iiat, smooth-edged blades are mounted on the rotor |34 and extend to closely adjacent the periphery. Removable insets |4| in the periphery of the cylinder `are provided with intersecting grooves to form rough surfaces. The material advances from right to left, as shown in Fig. 19,r and is discharged through the outlet |40 into discharging mechanism similar to that shown in Fig. 1 and related` figures. through pipes 43 and 44. Pipe 44 is connected to receiver 33 and the discharge end of the apparatus. the latter connection being to prevent uneven or intermittent flow of material throughthe rotating apparatus which otherwise might be 7 ycaused by the intermittent action of the discharge apparatus. An apparatus of this type is more gentle in its action onthe material than the, apparatus of the kind shown in Fig. 1 and therefore it is possible to obtain a fibrous pulp in which the 7;, fibers. are substantially intact per se while Steam is supplied, as in Fig. 1,v

thoroughly separated from each other. This apparatus is not as speedy in operation as that shownin Fig. 1 but is preferably used where a 'ne quality of pulp is desired with a minimum of mechanical destruction of the ber walls or where the pulp is to be chemically treated after debration. The time required for the passing of material in the apparatus shown in Figs. 19 through 22 may be from 2 to 3 minutes. The moisture content in the carrying out o'f the process by this apparatus should be between 1 to 3 parts of water per pound bone-dry material.

As shown at |43, a reducing valve may be provided in the steam inlet pipe to give a predetermined steam pressure in the apparatus.

In Figs. 23 and 24, I have shown a modification of the structure shown at 25 in Fig. 2. In this arrangement, one wall |5| of the plug chamber |50 is made movable by means of a hand screw |52 about a pivot pin |53. 'I'he walls, including the movable wall, are provided with back flow ,preventing edges |54. If the movable wall |5| is swung outwardly, the resistance to flow is less, and conversely, if the wall |5| is moved inwardly, the resistance is greater. This variation of resistance is desirable for diiIerent materials to be treated.

The pulp produced according to this invention is of a very uniform character, virtually free from slivers and large fiber bundles. This is especially the case when the previously described abrading apparatus of the disc-refining type is used.

For the production of wall board, insulation ,5 board and similar products, as well as certain 35 ters the receiver 33 and is fed by the screw 36 grades of cardboard, it is therefore possible to dispense with the screening of the pulp before it is formed into the finished product.

While I have described specic apparatus for carrying out my invention, it will be understood that the process may be carried out in a variety of different kinds of apparatuses and furthermore it will be understood that the process is not to be limited to anyy particular apparatus. Furthermore, it will be understood that variations may be made in structure and process, and process steps may be added to those described and that other variations may be made within the spirit 'and' scope of the invention.

While steam is the preferred iluid forming the environment in which the heating and deiibration takes place, it will be obvious that other gaseous environments may be u'sed. =While certain gases may be present, I have obtained good results in a pure steam atmosphere, chemically inert to the material.

What I claim is:

1. In apparatus for producing pulp, members forming apath of ow for material to be treated, means to supply steam to said members, said members being constructed to maintain pressure of steam in said path of iiow well above atmospheric pressure, means to feed the material into said path of ilow, means to remove the material from said path of ilow, rotatable abrading means in` said path of ow for debrating the material under pressure and in the presence of steam, and means to remove moisture from the material fed into said members.

2. In apparatus for producing pulp, members forming a path of flow for material to be treated, means to supply steam to said members, said members being constructed to maintain pressure of rsteam in said path of flow well above atmospheric pressure, means to feed the material into said path of flow, means to remove the material from said path of flow, rotatable abrading means in said path of flow for deiibrating the material under pressure and in the presence of steam, meansto remove moisture from the material fed into said members, and means to equalize steam pressure in said path of ilow.

3. In apparatus for producing pulp, members forming a path of flow for material to be treated, means to supply steam to said members, said members being constructed to maintain pressure of steam in said path of flow Well above atmospheric pressure, means to feed the material into said path of iiow, means to remove the material from said path of flow, rotatable abrading means in said path of flow for deiibrating the material under pressure and in the presence of steam, means to remove moisture from the material fed into said members, means to regulate the pressure of steam in said path of ilow, and means to independently control the rate of feed and rate of removal of said material.

4. In apparatus for producing pulp, members forming a path of iiow for material to be treated, means to supply steam to said members, said members being constructed to maintain pressure of steam in said path of iiow well above atmospheric pressure, means including a reciprocating plunger for feeding the material into said path offilow, means including series arranged alternately opened valves for removing the material from said path of flow, rotatable abrading means in said path of flow for defibrating the material under pressure and in the presence of steam,

means to remove moisture from the material fed into said members, variable speed means for controlling the action of said plunger, and variablev speed means for controlling the rate of opening of said valves.

5. In apparatus for producing pulp, members forming a, path of flow for material to be treated, means to supply steam to said members, said members being constructed to maintain pressure f of steam in said path of flow well above :atmospheric pressure, means including a reciprocating plunger for feeding the material into said path of flow, means including intermittently actuated Valves for removing the material from said path.

of flow, and rotatable abrading means in said path of flow for debrating the material under pressure and in the presence of steam.

6. In apparatus for 'producing pulp, members forming a path of flow for material to be treated, means to supply steam to said members, said members being constructed to maintain pressure of steam in said path of flow well above atmosf pheric pressure, means including a loose fittingl reciprocating plunger for feeding the material into said path of iiow, means to remove the material from said path of flow, and rotatable abrading means in said path of flow for debratingi the material under pressure and in the presence of steam.

7. In apparatus for producing pulp, members forming a path of ilow for material to be treated, means to supply steam to said members, said members being constructed to maintain pressure yof steam in said path ofiiow well above atmos- .pheric pressure, reciprocating means to feed the material into said path of iiow, reciprocating means to remove the material from said path of iiow, rotatable abrading means in said path of flow for debrating the material under pressure and in the presence of steam, and meansV to vary the speed of said feeding means andsaid removing means.

atmospheric pressure, means to feed the material into said path of ow, means to remove the material from said path of flow, rotatable abrading means in said path of ilow for deiibrating the material under pressure and inl the presence of steam, and meansto supply steam at substantially the same pressure to the supply and discharge side of said abrading means.

10. 'I'he combination with a housing, abrading apparatus within said housing and means to maintain pressure above atmospheric in said housing, of discharge apparatus including a conduit connected to said housing, valves arranged in series in said conduit, means to automatically alternately open and close .said valves,` and manual means to open said valves independently of the opening by said automatic means.

1l. The combination with a housing, abrading apparatus within said housing and means to maintain pressure above atmospheric within said housing, of discharge apparatus including a con'- `duit connected to said housing, a plurality of valves for controlling flow through said conduit,

each of said valves having a substantially flat seating surface having a narrow edge for contacting said seating surface, said edge being so narrow as to squeeze material between it and said seating surface to form a steam flow resisting packing and cushioning, and means to open and close said valves.

12. In apparatus of the character set forth, a housing, grinding apparatus within said housing including a plurality of discs, means to maintain quickly alternately pressure above atmosphericin said housing, iiex- 4 ible means to press one of said discs toward the other, and means to render said flexible means ineffective.

13. In apparatus of the character set forth, a housing, grinding apparatus within said housing including a plurality of discs, means to maintain pressure above atmospheric in said housing, a

stuffing box in said housing, a shaft secured to oneof said discs passing through said stuing box, and cooling means for said stuiiing box.

14. In apparatus of the character set forth, a housing, grinding apparatus within said housing including a plurality of discs, means to maintain of said path being proportioned for the conveyance therethrough of said material in a state of dryness such that substantially all water present is absorbed in said material, means tov supply steam to said conduit, said conduit means being formed with an inlet at one end and an outlet at the other endl and being otherwise closed, rotatable abrading means within `said conduit means 2,145,851 in said path of iiow for debrating the 'material under pressure and in the presence of steam, conveying means including a member in said conduit means and formed with a surface extending transversely to the lengthwise direction of said path, and means for imparting movement to said member in a direction causing said transversely positioned surface to exert force on the material in a direction having at least a component extending in the lengthwise direction of said path so that said surface directly engages said dry material and propels said material into and through said path, including said abrading means, and means to remove the material from said path of now, said last mentioned means being constructed and arranged to maintain pressure of steam in said path of flow well above atmospheric pressure.

16. In apparatus for producing pulp, conduit means forming a path o f iiow for fibrous material to be treated, the length and cross sectional area of said path being proportioned for the conveyance vtherethrough of said material in a state of formed with an inlet at one end and an outlet at the other end and being otherwise closed, 'rotatable abrading means within said conduit means in said path of ilow for deflbrating the material under pressure and in the presence of steam, feeding means including a member in said conduit means adjacent to said inlet and formed with a surface extending transversely to the lengthwise direction of said path, and means for imparting movement to said member in a direction causing said transversely positioned surface to exert force on the material in a direction having at least a component extending in the lengthwise direction of said path so that said surface directly engages said dry material and propels said material into and through said path, a screw conveyer vwithin said path of ilow between said feeding means and said abrading means for conveying the dry material through said path to said abrading means, and means to remove'the material through said outlet from said path of flow, said last mentioned means .being constructed and arranged to maintain pressure of steam in said path of flow well above atmospheric pressure.

ARNE JOHAN ARTHUR ASPLUND. 

